@STRING{ JCP     = "Journal of Computational Physics" }
@STRING{ I3ETBE  = "IEEE Transactions on Biomedical Engineering" }
@STRING{ I3ESPM   = "IEEE Signal Processing Magazines" }
@STRING{ I3ETM   = "IEEE Transactions on Magnetics" }
@STRING{ I3ETMI  = "IEEE Transactions on Medical Imaging" }
@STRING{ IPE     = "Inverse Problems in Engineering" }
@STRING{ PM     = "Physiological Measurements" }


@InProceedings{calderon80,
author = {Calderon, A.P.},
title = {On an Inverse Boundary Value Problem },
booktitle = {Seminar on Numerical Analysis and its Applications to Continuum Mechanics},
pages = {65-73},
year = {1980},
address = {Rio de Janeiro, Brasil},
organization = {LNCC}
}

@ARTICLE{barber87,
  AUTHOR =       "Barber,D.C. and Seagar, A.D.",
  TITLE =        "Applied Potential Tomography",
  JOURNAL =      "Clin. Phys. Physiol. Meas.",
  YEAR =         "1987",
  volume =       "8",
  pages =        "47-54"
}

@ARTICLE{santosa90,
  AUTHOR =       "Santosa, F. and Vogelius, M.",
  TITLE =        "A backprojection algorithm for electrical impedance imaging",
  JOURNAL =      "SIAM J. Appl. Math.",
  YEAR =         "1990",
  volume =       "50",
  pages =        "216-243",
}
@ARTICLE{hua93,
  AUTHOR =       "Hua, P. and Woo,E.J. and Webster,J.G. and Tompkins, W.J.",
  TITLE =        "Finite element modeling of eletrode-skin contact impedance
                    in electrical impedance tomography",
  JOURNAL =      I3ETBE,
  YEAR =         "1993",
  volume =       "40",
  number =       "4",
  pages =        "335-343"
}

@Book{malmivuo95,
author = {J.Malmivuo and R. Plonsey},
title = {Bioelectromagnetism - Principles and Applications of Bioelectric and                 Biomagnetic Fields},
publisher = {Oxford University Press},
year = {1995},
address = {New York}

@ARTICLE{duraiswami97,
  AUTHOR =       "Duraiswami,R. and Sarkar,K. and Chahine, G.L.",
  TITLE =        "Efficient {2-D} and {3-D} electrical impedance tomography
                    using dual reciprocity boundary element techniques",
  JOURNAL =      "Engineering Anal. with Boundary Elements",
  YEAR =         "1997"
}

@PHDTHESIS{metherall98,
  AUTHOR =       "P. Metherall",
  TITLE =        "Three Dimensional Electrical Impedance Tomography of the Human Thorax",
  SCHOOL =       "University of Sheffield",
  YEAR =         "1998"
}

@ARTICLE{han99,
  AUTHOR =       "Han, D.K. and Prosperetti, A.",
  TITLE =        "A shape decomposition technique in Electrical Impedance Tomography",
  JOURNAL =      JCP,
  YEAR =         "1999",
  volume =       "155",
  pages =        "75-95"
}
@ARTICLE{hartov00,
  AUTHOR =       "Hartov, A. and Mazzarese, R.A. and Reiss, F.R. and
                  Kerner, T.E. ans Osterman, S. and Williams, D.B. and
                  Paulsen, K.",
  TITLE =        "A Multichannel Continuously Selectable Multifrequency
                  Electrical Impedance Spectroscopy Measurement System",
  JOURNAL =      I3ETBE,
  YEAR =         "2000",
  volume =       "47",
  number =       "1",
  pages =        "49-58"
}

@ARTICLE{munck00,
  AUTHOR =       "J. C. Munck and T.J.C. Faes and R. M. Heetaar",
  TITLE =        "The Boundary Element Method in the Forward and Inverse Problem of Electrical Impedance Tomography",
  JOURNAL =      I3ETBE,
  YEAR =         "2000",
  volume =       "47",
  number =       "06",
  pages =        "792-800",
  month =        "June"
}

@ARTICLE{hsiao01,
  AUTHOR =       "C. T. Hsiao and G. Chahine and N. Gumerov",
  TITLE =        "Application of a Hybrid Genetic/Powell Algorithm and a
                    Boundary Element Method to Electrical Impedance Tomography",
  JOURNAL =      JCP,
  YEAR =         "2001",
  volume =       "173",
  pages =        "433-454"
}

@ARTICLE{trelp01,
  AUTHOR =       "M. Trelp and A. Hamler and M. Jesenik and B. Stumberger",
  TITLE =        "The use of dual-reciprocity Method for Electrical Impedance Tomography",
  JOURNAL =      I3ETM,
  YEAR =         "2001",
  volume =       "37",
  number =       "5",
  pages =        "3221-3224"
}

@ARTICLE{lesnic01,
  AUTHOR =       "D. Lesnic",
  TITLE =        "A numerical investigation of the inverse potential conductivity problem in a circular inclusion",
  JOURNAL =      IPE,
  YEAR =         "2001",
  volume =       "9",
  number =       "1",
  pages =        "1-17",
  annote=          "A SER OBTIDO"
}

@Article{saul01,
author = {Saulnier,G.J. and Blue,R.S. and Newell,J.C. and Isaacson,D and Edic,P.M.},
title = {Electrical Impedance Tomography},
journal = I3ESPM,
year = {2001},
volume = {18},
number = {6},
pages = {31-43}
}


@ARTICLE{bayford01,
  AUTHOR =       "Bayford, R.H. and Gibson,A. and Tizzard,
                  A. and Tidswell, T. and  Holder, D.S.",
  TITLE =        "Solving the forward problem in electrical impedance tomography
                  for the human head using {IDEAS}, a finite element modelling tool",
  JOURNAL =      PM,
  YEAR =         "2001",
  volume =       "22",
  pages =        "55-64"
}



@ARTICLE{kerner02,
  AUTHOR =       "T.E. Kerner and K.D. Paulsen and A. Hartov and S.K. Soho and S.P. Poplack",
  TITLE =        "Electrical impedance spectroscopy of the breast:
                  Clinical imaging results in 26 subjects",
  JOURNAL =      I3ETMI,
  YEAR =         "2002",
  volume =       "21",
  number =       "6",
  pages =        "638-645"
}

@ARTICLE{poly02,
  AUTHOR =       "N. Polydorides and W.R.B. Lionheart and H. {McCann}",
  TITLE =        "{Krylov} subspace iterative thechniques:
                {On} the  brain activity with electrical impedance tomography",
  JOURNAL =      I3ETMI,
  YEAR =         "2002",
  volume =       "21",
  number =       "6",
  pages =        "596-603",
  month =        "June",
  annote =         "**** A IMPRIMIR ****"
}

@INCOLLECTION{bevi03,
  AUTHOR =       "J. S. Bevilacqua",
  TITLE =        "Modelagem em Biomatem?tica",
  BOOKTITLE =    "Notas em Matem?tica Aplicada",
  PUBLISHER =    "SBMAC",
  YEAR =         "2003"
}

@INPROCEEDINGS{mello04,
  AUTHOR =       "L.A.M. Mello and C.R. Lima and E.C.N. Silva",
  TITLE =        "Algoritmo de reconstru??o de imagens tridimensionais atrav?s da
                  tomografia por imped?ncia el?trica
                    baseado no m?todo de otimiza??o topol?gica",
  BOOKTITLE =    "CILAMCE - Congresso Ibero Latino Americano sobre
                  M?todos Computacionais em Engenharia",
  YEAR =         "2004",
  pages =        "15p.",
  organization = "ABMEC"
}


@InProceedings{araujo04,
author = {Araujo, D. R. M. and Lemonge, A.C.C. and Barra, L. P. S. and Barbosa, H.J.C.},
title = {Shape Optimization of Shafts Under Torsion Using Genetic Algorithm},
booktitle = {XXV CILAMCE - Iberian Latin American Congress on Computational Methods in Engineering},
year = {2004},
address = {Recife, Brasil},
organization = {ABMEC - Associa??o Brasileira de Mec?nica Computacional}
}


}
@ARTICLE{trigo04,
  AUTHOR =       "Trigo, F.C. and Lima, R.G. and Amato, M.B.P.",
  TITLE =        "Electrical Impedance Tomography Using Extended Kalman Filter",
  JOURNAL =      I3ETBE,
  YEAR =         "2004",
  volume =       "51",
  number =       "1",
  pages =        "72-81"
}



@Article{seo04,
author = {Seo, J.K. and Kwon,O. and Ammari,H. and Woo,E.J.},
title = {A Mathematical Model for Breast Cancer Lesion Estimation: Electrical Impedance Technique Using TS2000 Commercial System},
journal = I3ETBE,
year = {2004},
volume = {51},
number = {11},
pages = {1898-1906}
}


@Article{kim04,
author = {Kim, M.C. and Kim, K.Y. and Kim,S.},
title = {Phase Boundary Estimation in Two-Phase Flows with
         Electrical Impedance Tomography },
journal = {Int. Comm. Heat Transfer },
year = {2004},
volume = {31},
number = {8},
pages = {1105-1114}
}


@article{park2008,

author = {Park, B. G. and Moon, J. H. and Lee, B. S. and Kim, S.},

title = {An electrical resistance tomography technique for the monitoring of a radioactive waste separation process},

journal = {International Communications in Heat and Mass Transfer},

volume = {35},

number = {10},

pages = {1307-1310},

abstract = {An electrical resistance tomography (ERT) technique is suggested to monitor a radioactive waste separation process. This paper presents analytical results for a simple model problem to estimate the boundary between two distinct waste streams in a rotating separator as well as the conductivity value of each stream. To solve this highly non-linear identification problem, the particle swarm optimization (PSO) algorithm is successfully introduced. The results show the feasibility of the ERT for monitoring the separation process. (c) 2008 Elsevier Ltd. All rights reserved.},

year = {2008}

}

@article{partridge2007,

author = {Partridge, P. W. and Wrobel, L. C.},

title = {An inverse geometry problem for the localisation of skin tumours by thermal analysis},

journal = {Engineering Analysis with Boundary Elements},

volume = {31},

pages = {803-811},

abstract = {In this paper, the dual reciprocity method (DRM) is coupled to a genetic algorithm (GA) in an inverse procedure through which the size and location of a skin tumour may be obtained from temperature measurements at the skin surface. The GA is an evolutionary process which does not require the calculation of sensitivities, search directions or the definition of initial guesses. The DRM in this case requires no internal nodes. It is also shown that the DRM approximation function used is not an important factor for the problem considered here. Results are presented for tumours of different sizes and positions in relation to the skin surface. (C) 2007 Elsevier Ltd. All rights reserved.},

year = {2007}

}

@article{rus2002,

author = {Rus, G. and Gallego, R.},

title = {Optimization algorithms for identification inverse problems with the boundary element method},

journal = {Engineering Analysis with Boundary Elements},

volume = {26},

number = {4},

pages = {315-327},

abstract = {In this paper the most suitable algorithms for unconstrained optimization now available applied to an identification inverse problem in elasticity using the boundary element method (BEM) are compared, Advantage is taken of the analytical derivative of the whole integral C, equation of the BEM with respect to the variation of the geometry, direct differentiation, which can be used to obtain the gradient of the cost function to be optimized. (C) 2002 Elsevier Science Ltd. All rights reserved.},

year = {2002}

}

@article{stasiak2007,

author = {Stasiak, M. and Sikora, J. and Filipowicz, S. F. and Nita, K.},

title = {Principal component analysis and artificial neural network approach to electrical impedance tomography problems approximated by multi-region boundary element method},

journal = {Engineering Analysis with Boundary Elements},

volume = {31},

pages = {713-720},

abstract = {The idea of electrical impedance tomography (FIT) is to evaluate conductivity or permittivity distribution inside the examined object by measuring the voltages between electrodes placed on its surface. In this paper, EIT as a default 3D diagnostic method of the breast cancer is suggested. The breast was modelled as a hemisphere consists of two spatially homogenous areas with different conductivity. In order to determine the distribution of potential in the breast model, a multi-region boundary element method (BEM) was implemented. In this paper, a multi-region BEM with quadratic interpolation function for the flat, triangular surface elements was introduced. The inverse problem solution provided the identification of the size and the position of the anomalies in the breast tissue. For this purpose the efficient method based on principal component analysis (PCA) and the artificial neural network (ANN) was used. PCA applied to EIT data allows reducing dimensionality of measured data for 3D space and removing the unused part of information, usually corresponding to noise and interrelated variables. ANN method allows to obtain the results of inverse problem solution in real-time. (C) 2007 Elsevier Ltd. All rights reserved.},

year = {2007}

}


@article{lima2007,
  author={Cicero R de Lima and Luis A M Mello and Raul Gonzalez Lima and Emilio C N Silva},
  title={Electrical impedance tomography through constrained sequential linear programming: a topology optimization approach},
  journal={Measurement Science and Technology},
  volume={18},
  number={9},
  pages={2847-2858},
  url={http://stacks.iop.org/0957-0233/18/2847},
  year={2007},
  abstract={Electrical impedance tomography (EIT) is an imaging method that estimates conductivity distribution inside a body. In EIT, images are obtained by applying a sequence of low intensity electrical currents through electrodes attached to the body. Although in EIT there are serious difficulties to obtain a high-quality conductivity image, for medical applications this technology is safer and cheaper than other tomography techniques. The EIT deals with an inverse problem in which given the measured voltages on electrodes and a finite element (FE) model, it estimates the conductivity distribution, which are parameters of the FE model. In this work, the topology optimization method is applied as a reconstruction algorithm to obtain absolute images in EIT. It is an optimization method that has been applied successfully to structural mechanical applications and consists of systematically finding a conductivity distribution (or material distribution) in the domain that minimizes the difference between measured voltages and voltages calculated by using a computational model. This algorithm combines the finite element method and sequential linear programming (SLP) to solve the inverse problem of EIT. The SLP allows us to easily apply some regularization schemes based on included constraints in the topology optimization problem. Constraints based on image tuning control and weighted distance interpolation (WDI) are proposed, while a material model is applied to ensure the relaxation of the optimization problem. A new formulation to analytically perform the sensitivity analysis is proposed, using Maxwell's reciprocity theorem. To illustrate, the implemented algorithm is applied to obtain conductivity image distributions of some 2D examples using numerical and experimental data.}
}


@ARTICLE{cheney99,
    author = {Margaret Cheney and David Isaacson and Jonathan C. Newell},
    title = {Electrical Impedance Tomography},
    journal = {SIAM Review},
    year = {1999},
    volume = {41},
    pages = {85--101}
}

@article{zlochiver06,
Author = {Zlochiver, S and Freimark, D and Arad, M and Adunsky, A and Abboud, S},
Title = {{Parametric EIT for monitoring cardiac stroke volume}},
Journal = {{PHYSIOLOGICAL MEASUREMENT}},
Year = {{2006}},
Volume = {{27}},
Number = {{5, Sp. Iss. SI}},
Pages = {{S139-S146}},
Month = {{MAY}},
DOI = {{10.1088/0967-3334/27/5/S12}},
ISSN = {{0967-3334}},
Unique-ID = {{ISI:000237889100014}},
}
